Difference between revisions of "Limits and L'Hospital's Rule"
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And then so on and forth so that means the limit does not exist. | And then so on and forth so that means the limit does not exist. | ||
So if you | So if you want to compute this first limit we can't use L'Hospital's Rule and this is how we do it. | ||
Start <math display=inline> \lim_{x \to \infty } {x + cos x \over x}</math> | Start <math display=inline> \lim_{x \to \infty } {x + cos x \over x}</math> | ||
#<math display=inline> \lim_{x \to \infty } ({1 + {cos \over x}}) </math> | #<math display=inline> \lim_{x \to \infty } ({1 + {cos \over x}}) </math> | ||
And then we will get the answer 1. because cos x only can be between 1 to -1 but it has been divided by Infinite so we can say it is almost zero and then + 1 so we will get 1. | And then we will get the answer 1. because cos x only can be between 1 to -1 but it has been divided by Infinite so we can say it is almost zero and then + 1 so we will get 1. |
Revision as of 13:44, 13 September 2021
- L'Hospital's Rule 1
- L'Hospital's Rule 2
there are some of the problems that can't use the L'Hospital's Rule such as:
If you are only using the L'Hospital's Rule this is what you will get:
Start
- Derivatives
- Derivatives
- Derivatives
And then so on and forth so that means the limit does not exist.
So if you want to compute this first limit we can't use L'Hospital's Rule and this is how we do it.
Start
And then we will get the answer 1. because cos x only can be between 1 to -1 but it has been divided by Infinite so we can say it is almost zero and then + 1 so we will get 1.